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Abstract

Previously, we and others have shown that rodent neural progenitor cells (NPCs) can support functional recovery after cervical and thoracic transection injuries. To extend these observations to a more clinically relevant model of spinal cord injury, we performed unilateral midcervical contusion injuries in Fischer 344 rats. Two-weeks later, E14-derived syngeneic spinal cord-derived multi-potent NPCs were implanted into the lesion cavity. Control animals received either no grafts or fibroblast grafts. The NPCs differentiated into all three neural lineages (neurons, astrocytes, oligodendrocytes) and robustly extended axons into the host spinal cord caudal and rostral to the lesion. Graft-derived axons grew into host gray matter and expressed synaptic proteins in juxtaposition with host neurons. Animals that received NPC grafts exhibited significant recovery of forelimb motor function compared with the two control groups (analysis of variance p < 0.05). Thus, NPC grafts improve forelimb motor outcomes after clinically relevant cervical contusion injury. These benefits are observed when grafts are placed two weeks after injury, a time point that is more clinically practical than acute interventions, allowing time for patients to stabilize medically, simplifying enrollment in clinical trials, and enhancing predictability of spontaneous improvement in control groups.

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References

National Spinal Cord Injury Statistical Center (2016). Spinal Cord Injury (SCI) Facts and Figures at a Glance. Available at: www.nscisc.uab.edu. Accessed January 31, 2018 .

Anderson

K.D.

, Friden

, and Lieber

R.L.

(2009). Acceptable benefits and risks associated with surgically improving arm function in individuals living with cervical spinal cord injury. Spinal Cord, 47, 334–338.

, Wang

, Graham

, McHale

, Gao

, Wu

, Brock

, Blesch

, Rosenzweig

E.S.

, Havton

L.A.

, Zheng

, Conner

J.M.

, Marsala

, and Tuszynski

M.H.

(2012). Long-distance growth and connectivity of neural stem cells after severe spinal cord injury. Cell, 150, 1264–1273.

Cummings

B.J.

, Uchida

, Tamaki

S.J.

, Salazar

D.L.

, Hooshmand

, Summers

, Gage

F.H.

, and Anderson

A.J.

(2005). Human neural stem cells differentiate and promote locomotor recovery in spinal cord-injured mice. Proc. Natl. Acad. Sci. U. S. A., 102, 14069–14074.

Kadoya

, Lu

, Nguyen

, Lee-Kubli

, Kumamaru

, Yao

, Knackert

, Poplawski

, Dulin

J.N.

, Strobl

, Takashima

, Biane

, Conner

, Zhang

S.C.

, and Tuszynski

M.H.

(2016). Spinal cord reconstitution with homologous neural grafts enables robust corticospinal regeneration. Nat. Med., 22, 479–487.

, Woodruff

, Wang

, Graham

, Hunt

, Wu

, Boehle

, Ahmad

, Poplawski

, Brock

, Goldstein

L.S.

, and Tuszynski

M.H.

(2014). Long-distance axonal growth from human induced pluripotent stem cells after spinal cord injury. Neuron, 83, 789–796.

Keirstead

H.S.

, Nistor

, Bernal

, Totoiu

, Cloutier

, Sharp

, and Steward

(2005). Human embryonic stem cell-derived oligodendrocyte progenitor cell transplants remyelinate and restore locomotion after spinal cord injury. J. Neurosci., 25, 4694–4705.

Cizkova

, Kakinohana

, Kucharova

, Marsala

, Johe

, Hazel

, Hefferan

M.P.

, and Marsala

(2007). Functional recovery in rats with ischemic paraplegia after spinal grafting of human spinal stem cells. Neuroscience, 147, 546–560.

Kwon

B.K.

, Soril

L.J.

, Bacon

, Beattie

M.S.

, Blesch

, Bresnahan

J.C.

, Bunge

M.B.

, Dunlop

S.A.

, Fehlings

M.G.

, Ferguson

A.R.

, Hill

C.E.

, Karimi-Abdolrezaee

, Lu

, McDonald

J.W.

, Muller

H.W.

, Oudega

, Rosenzweig

E.S.

, Reier

P.J.

, Silver

, Sykova

, Xu

X.M.

, Guest

J.D.

, and Tetzlaff

(2013). Demonstrating efficacy in preclinical studies of cellular therapies for spinal cord injury—how much is enough?. Exp. Neurol., 248, 30–44.

10.

Scheff

S.W.

, Rabchevsky

A.G.

, Fugaccia

, Main

J.A.

, and Lumpp

J.E.

Jr . (2003). Experimental modeling of spinal cord injury: characterization of a force-defined injury device. J. Neurotrauma, 20, 179–193.

11.

, Graham

, Wang

, Wu

, and Tuszynski

(2014). Promotion of survival and differentiation of neural stem cells with fibrin and growth factor cocktails after severe spinal cord injury. J. Vis. Exp. e50641.

12.

Robinson

and Lu

(2017). Optimization of trophic support for neural stem cell grafts in sites of spinal cord injury. Exp. Neurol., 291, 87–97.

13.

Montoya

C.P.

, Campbell-Hope

L.J.

, Pemberton

K.D.

, and Dunnett

S.B.

(1991). The “staircase test”: a measure of independent forelimb reaching and grasping abilities in rats. J. Neurosci. Methods, 36, 219–228.

14.

Mullen

R.J.

, Buck

C.R.

, and Smith

A.M.

(1992). NeuN, a neuronal specific nuclear protein in vertebrates. Development, 116, 201–211.

15.

Sun

, Cornwell

, Li

, Peng

, Osorio

M.J.

, Aalling

, Wang

, Benraiss

, Lou

, Goldman

S.A.

, and Nedergaard

(2017). SOX9 Is an astrocyte-specific nuclear marker in the adult brain outside the neurogenic regions. J. Neurosci., 37, 4493–4507.

16.

Soloviev

M.M.

, Ciruela

, Chan

W.Y.

, and McIlhinney

R.A.

(2000). Molecular characterisation of two structurally distinct groups of human homers, generated by extensive alternative splicing. J. Mol. Biol., 295, 1185–1200.

17.

Kneussel

and Betz

(2000). Receptors, gephyrin and gephyrin-associated proteins: novel insights into the assembly of inhibitory postsynaptic membrane specializations. J. Physiol., 525 Pt 1, 1-–.

18.

Lynskey

J.V.

, Sandhu

F.A.

, Dai

H.N.

, McAtee

, Slotkin

J.R.

, MacArthur

, and Bregman

B.S.

(2006). Delayed intervention with transplants and neurotrophic factors supports recovery of forelimb function after cervical spinal cord injury in adult rats. J. Neurotrauma, 23, 617–634.

19.

Jakeman

L.B.

and Reier

P.J.

(1991). Axonal projections between fetal spinal cord transplants and the adult rat spinal cord: a neuroanatomical tracing study of local interactions. J. Comp. Neurol., 307, 311–334.

20.

Bregman

B.S.

, McAtee

, Dai

H.N.

, and Kuhn

P.L.

(1997). Neurotrophic factors increase axonal growth after spinal cord injury and transplantation in the adult rat. Exp Neurol, 148, 475–494.

21.

Bonner

J.F.

, Connors

T.M.

, Silverman

W.F.

, Kowalski

D.P.

, Lemay

M.A.

, and Fischer

(2011). Grafted neural progenitors integrate and restore synaptic connectivity across the injured spinal cord. J. Neurosci., 31, 4675–4686.

22.

Armbruster

B.N.

, Li

, Pausch

M.H.

, Herlitze

, and Roth

B.L.

(2007). Evolving the lock to fit the key to create a family of G protein-coupled receptors potently activated by an inert ligand. Proc. Natl. Acad. Sci. U. S. A., 104, 5163–5168.

23.

Fawcett

J.W.

, Curt

, Steeves

J.D.

, Coleman

W.P.

, Tuszynski

M.H.

, Lammertse

, Bartlett

P.F.

, Blight

A.R.

, Dietz

, Ditunno

, Dobkin

B.H.

, Havton

L.A.

, Ellaway

P.H.

, Fehlings

M.G.

, Privat

, Grossman

, Guest

J.D.

, Kleitman

, Nakamura

, Gaviria

, and Short

(2007). Guidelines for the conduct of clinical trials for spinal cord injury as developed by the ICCP panel: spontaneous recovery after spinal cord injury and statistical power needed for therapeutic clinical trials. Spinal Cord, 45, 190–205.

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Rodent Neural Progenitor Cells Support Functional Recovery after Cervical Spinal Cord Contusion

Abstract

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